Towards finite element exterior calculus over manifolds: commuting projections, geometric variational crimes, and approximation errors

We survey recent contributions to finite element exterior calculus over manifolds and surfaces within a comprehensive formalism for the error analysis of vector-valued partial differential equations over manifolds. Our primary focus is on uniformly bounded commuting projections over manifolds: these projections map from Sobolev de Rham complexes onto finite element de Rham complexes, commute with the differential operators, and satisfy uniform bounds in Lebesgue norms. They enable the Galerkin theory of Hilbert complexes for a large range of intrinsic finite element methods over manifolds. However, these intrinsic finite element methods are generally not computable and thus primarily of theoretical interest. This leads to our second point: estimating the geometric variational crime incurred by transitioning to computable approximate problems. Lastly, our third point addresses how to estimate the approximation error of the intrinsic finite element method in terms of the mesh size. If the solution is not continuous, then such an estimate is achieved via modified Cl\'ement or Scott-Zhang interpolants that facilitate a broken Bramble--Hilbert lemma.